Merge git://git.infradead.org/battery-2.6

static void find_main_battery(void)

{

	struct device *dev;

	struct power_supply *bat, *batm;

	struct power_supply *bat = NULL;

	struct power_supply *max_charge_bat = NULL;

	struct power_supply *max_energy_bat = NULL;

	union power_supply_propval full;

	int max_charge = 0;

	int max_energy = 0;

	main_battery = NULL;

	batm = NULL;

	list_for_each_entry(dev, &power_supply_class->devices, node) {

		bat = dev_get_drvdata(dev);

		/* If none of battery devices cantains 'use_for_apm' flag,

		   choice one with maximum design charge */

		if (!PSY_PROP(bat, CHARGE_FULL_DESIGN, &full)) {

		if (bat->use_for_apm) {

			/* nice, we explicitly asked to report this battery. */

			main_battery = bat;

			return;

		}

		if (!PSY_PROP(bat, CHARGE_FULL_DESIGN, &full) ||

				!PSY_PROP(bat, CHARGE_FULL, &full)) {

			if (full.intval > max_charge) {

				batm = bat;

				max_charge_bat = bat;

				max_charge = full.intval;

			}

		} else if (!PSY_PROP(bat, ENERGY_FULL_DESIGN, &full) ||

				!PSY_PROP(bat, ENERGY_FULL, &full)) {

			if (full.intval > max_energy) {

				max_energy_bat = bat;

				max_energy = full.intval;

			}

		}

	}

		if (bat->use_for_apm)

	if ((max_energy_bat && max_charge_bat) &&

			(max_energy_bat != max_charge_bat)) {

		/* try guess battery with more capacity */

		if (!PSY_PROP(max_charge_bat, VOLTAGE_MAX_DESIGN, &full)) {

			if (max_energy > max_charge * full.intval)

				main_battery = max_energy_bat;

			else

				main_battery = max_charge_bat;

		} else if (!PSY_PROP(max_energy_bat, VOLTAGE_MAX_DESIGN,

								  &full)) {

			if (max_charge > max_energy / full.intval)

				main_battery = max_charge_bat;

			else

				main_battery = max_energy_bat;

		} else {

			/* give up, choice any */

			main_battery = max_energy_bat;

		}

	} else if (max_charge_bat) {

		main_battery = max_charge_bat;

	} else if (max_energy_bat) {

		main_battery = max_energy_bat;

	} else {

		/* give up, try the last if any */

		main_battery = bat;

	}

	if (!main_battery)

		main_battery = batm;

}

static int calculate_time(int status)

static int calculate_time(int status, int using_charge)

{

	union power_supply_propval charge_full, charge_empty;

	union power_supply_propval charge, I;

	union power_supply_propval full;

	union power_supply_propval empty;

	union power_supply_propval cur;

	union power_supply_propval I;

	enum power_supply_property full_prop;

	enum power_supply_property full_design_prop;

	enum power_supply_property empty_prop;

	enum power_supply_property empty_design_prop;

	enum power_supply_property cur_avg_prop;

	enum power_supply_property cur_now_prop;

	if (MPSY_PROP(CHARGE_FULL, &charge_full)) {

		/* if battery can't report this property, use design value */

		if (MPSY_PROP(CHARGE_FULL_DESIGN, &charge_full))

	if (MPSY_PROP(CURRENT_AVG, &I)) {

		/* if battery can't report average value, use momentary */

		if (MPSY_PROP(CURRENT_NOW, &I))

			return -1;

	}

	if (MPSY_PROP(CHARGE_EMPTY, &charge_empty)) {

		/* if battery can't report this property, use design value */

		if (MPSY_PROP(CHARGE_EMPTY_DESIGN, &charge_empty))

			charge_empty.intval = 0;

	if (using_charge) {

		full_prop = POWER_SUPPLY_PROP_CHARGE_FULL;

		full_design_prop = POWER_SUPPLY_PROP_CHARGE_FULL_DESIGN;

		empty_prop = POWER_SUPPLY_PROP_CHARGE_EMPTY;

		empty_design_prop = POWER_SUPPLY_PROP_CHARGE_EMPTY;

		cur_avg_prop = POWER_SUPPLY_PROP_CHARGE_AVG;

		cur_now_prop = POWER_SUPPLY_PROP_CHARGE_NOW;

	} else {

		full_prop = POWER_SUPPLY_PROP_ENERGY_FULL;

		full_design_prop = POWER_SUPPLY_PROP_ENERGY_FULL_DESIGN;

		empty_prop = POWER_SUPPLY_PROP_ENERGY_EMPTY;

		empty_design_prop = POWER_SUPPLY_PROP_CHARGE_EMPTY;

		cur_avg_prop = POWER_SUPPLY_PROP_ENERGY_AVG;

		cur_now_prop = POWER_SUPPLY_PROP_ENERGY_NOW;

	}

	if (MPSY_PROP(CHARGE_AVG, &charge)) {

		/* if battery can't report average value, use momentary */

		if (MPSY_PROP(CHARGE_NOW, &charge))

	if (_MPSY_PROP(full_prop, &full)) {

		/* if battery can't report this property, use design value */

		if (_MPSY_PROP(full_design_prop, &full))

			return -1;

	}

	if (MPSY_PROP(CURRENT_AVG, &I)) {

	if (_MPSY_PROP(empty_prop, &empty)) {

		/* if battery can't report this property, use design value */

		if (_MPSY_PROP(empty_design_prop, &empty))

			empty.intval = 0;

	}

	if (_MPSY_PROP(cur_avg_prop, &cur)) {

		/* if battery can't report average value, use momentary */

		if (MPSY_PROP(CURRENT_NOW, &I))

		if (_MPSY_PROP(cur_now_prop, &cur))

			return -1;

	}

	if (status == POWER_SUPPLY_STATUS_CHARGING)

		return ((charge.intval - charge_full.intval) * 60L) /

		       I.intval;

		return ((cur.intval - full.intval) * 60L) / I.intval;

	else

		return -((charge.intval - charge_empty.intval) * 60L) /

			I.intval;

		return -((cur.intval - empty.intval) * 60L) / I.intval;

}

static int calculate_capacity(int using_charge)

	info->units = APM_UNITS_MINS;

	if (status.intval == POWER_SUPPLY_STATUS_CHARGING) {

		if (MPSY_PROP(TIME_TO_FULL_AVG, &time_to_full)) {

			if (MPSY_PROP(TIME_TO_FULL_NOW, &time_to_full))

				info->time = calculate_time(status.intval);

			else

		if (!MPSY_PROP(TIME_TO_FULL_AVG, &time_to_full) ||

				!MPSY_PROP(TIME_TO_FULL_NOW, &time_to_full)) {

			info->time = time_to_full.intval / 60;

		} else {

			info->time = calculate_time(status.intval, 0);

			if (info->time == -1)

				info->time = calculate_time(status.intval, 1);

		}

	} else {

		if (MPSY_PROP(TIME_TO_EMPTY_AVG, &time_to_empty)) {

			if (MPSY_PROP(TIME_TO_EMPTY_NOW, &time_to_empty))

				info->time = calculate_time(status.intval);

			else

		if (!MPSY_PROP(TIME_TO_EMPTY_AVG, &time_to_empty) ||

			      !MPSY_PROP(TIME_TO_EMPTY_NOW, &time_to_empty)) {

			info->time = time_to_empty.intval / 60;

		} else {

			info->time = calculate_time(status.intval, 0);

			if (info->time == -1)

				info->time = calculate_time(status.intval, 1);

		}

	}